CN216387885U - Intelligent measurement and control device for switch cabinet - Google Patents

Abstract

The utility model discloses an intelligent measurement and control device of a switch cabinet, which comprises a main control panel and an installation back plate. The main control panel is provided with a display part, a touch part, a plurality of knob parts, a dynamic simulation part, a voice prompt part and an induction detection port. A main control module is also arranged between the main control panel and the mounting back plate; the main control module is provided with a temperature and humidity control module, a dynamic simulation control module, a wireless temperature measurement module, a voice prompt module, an in-cabinet control module and an automatic induction control module. The dynamic simulation control module is connected with the dynamic simulation part; the wireless temperature measurement module is connected with the temperature and humidity control module; the voice prompt module is connected with the voice prompt part; the control module in the cabinet is connected with the touch part; the automatic induction control module is connected with the induction detection port. The utility model solves the technical problem of single function of the switch cabinet alarm in the prior art.

Description

Intelligent measurement and control device for switch cabinet

Technical Field

The utility model relates to the technical field of electrical equipment, in particular to an intelligent measurement and control device for a switch cabinet.

Background

A switchgear is a power transmission device commonly used in a power transmission system, and is mainly composed of electrical components such as a load switch, a fuse, and an electric operating mechanism. The electric operating mechanism is used for operating the on and off of the load switch, and a user can remotely operate the high-voltage switch cabinet in a monitoring room of the high-voltage switch cabinet through the electric operating mechanism. When the equipment of the switch cabinet is in an operating state, the temperature in the cabinet is easy to rise due to more heating components in the cabinet. When the temperature in the cabinet rises too high, the mechanical performance and the electrical performance of the electrical equipment are reduced, and finally, the working failure of the high-voltage electrical equipment is caused, even serious accidents are caused. In order to ensure that the high-voltage electrical system operates safely within its operating life, the temperature rise in the cabinet must be controlled within the permissible temperature specified. Based on this, chinese patent CN201521021900 discloses a switch cabinet with an alarm function, in which a temperature sensor and an alarm are installed. When the temperature in the cabinet exceeds the preset range, the alarm can send out an alarm signal to remind a user to take measures in time, so that safety accidents are avoided.

However, the switch cabinet disclosed above is too single in function, and can alarm when the temperature in the cabinet is too high, but the switch cabinet cannot automatically detect or eliminate a component with a fault. Maintenance personnel usually associate high temperature with excessive load, and the switch cabinet has many components inside and cannot be operated randomly; therefore, the maintenance personnel usually do not examine the components in the cabinet one by one, which leads to the potential safety hazard that may exist not to be eliminated in time. Therefore, the situation that high-temperature alarm and even dangerous case occur again in the switch cabinet is difficult to avoid.

SUMMERY OF THE UTILITY MODEL

Therefore, the intelligent measurement and control device for the switch cabinet is needed to solve the technical problem of single function of the switch cabinet alarm in the background technology.

The utility model provides a cubical switchboard intelligence measurement and control device which includes: a main control panel and a mounting backboard; the main control panel and the installation back plate are arranged oppositely. The main control panel is provided with a display part, a touch part, a plurality of knob parts, a dynamic simulation part, a voice prompt part and an induction detection port. The display part is arranged above the side of the main control panel; the display part is provided with a visual window and an output working state indicating area; the output working state indication area is arranged below the visual window. The plurality of knob parts are respectively arranged at two sides of the dynamic simulation part; the dynamic simulation part is provided with a two-trolley test area, a two-trolley working area, a circuit breaker closing area, a circuit breaker dividing area, a grounding switch closing area and a grounding switch dividing area; the two handcart test areas and the two handcart working areas are respectively arranged on two sides of the circuit breaker on-position area and the circuit breaker off-position area; the grounding knife closing area and the grounding knife separating area are arranged below the handcart test area and the handcart working area. The voice prompt part and the induction detection port are arranged on the other side of the dynamic simulation part relative to the visual window, and the voice prompt part is arranged below the induction detection port. A main control module is also arranged between the main control panel and the mounting back plate; the main control module is provided with a temperature and humidity control module, a dynamic simulation control module, a wireless temperature measurement module, a voice prompt module, an in-cabinet control module and an automatic induction control module. The temperature and humidity control module is connected with the visual window; the dynamic simulation control module is connected with the dynamic simulation part; the wireless temperature measurement module is connected with the temperature and humidity control module; the voice prompt module is connected with the voice prompt part; the control module in the cabinet is connected with the touch part; the automatic induction control module is connected with the induction detection port.

Further, the installation backplate is provided with first sensor connection port, second sensor connection port and wireless sensing receiver.

Furthermore, the first sensor connection port and the second sensor connection port are respectively connected with the temperature and humidity control module.

Furthermore, the wireless sensing receiver is connected with the wireless temperature measuring module.

Further, the dynamic simulation part is provided with an energy storage indicator lamp; the energy storage indicator lamp is arranged on the adjacent side of the circuit breaker closed area.

Furthermore, the dynamic simulation part is provided with a high-voltage charged display and locking area; the high-voltage electrified display and locking area is arranged below the energy storage indicator lamp.

Furthermore, the main control module is provided with a high-voltage electrification control module; the high-voltage electrification control module is in control connection with the high-voltage electrification display and locking area.

Further, the visual window is provided with an LCD backlight function; the automatic induction control module controls the LCD backlight function.

Furthermore, the automatic induction control module is connected with the in-cabinet control module.

In summary, the intelligent measurement and control device of the switch cabinet is provided with a main control panel and an installation back plate respectively; the main control panel is respectively provided with a display part, a touch part, a plurality of knob parts, a dynamic simulation part, a voice prompt part and an induction detection port; the main control panel with be equipped with host system between the installation backplate, and, host system is the control connection temperature and humidity control module, dynamic simulation control module, wireless temperature measurement module, voice prompt module, in cabinet control module, auto-induction control module and high-voltage electrification control module respectively. Therefore, the display part can respectively indicate the main loop current, the voltage, the active power, the reactive power, the power factor, the electric energy and other power parameters of the external switch cabinet; the touch control part can control the display part; the knob parts can control an external switch cabinet; therefore, a user can remotely monitor the state of the switch cabinet in real time through the intelligent measurement and control device for the switch cabinet. In addition, the dynamic simulation portion can pass through according to the circuit scheme of the connected switch cabinet the car test area, the car work area, the circuit breaker on-position area, the circuit breaker off-position area, the grounding switch on-position area, the grounding switch off-position area, the energy storage indicator light and the high-voltage live display and locking area indicate the working state of the switch cabinet in real time, and then, when the switch cabinet is in an abnormal working state, the switch cabinet can assist a user to quickly analyze and judge the reason of the abnormality. Furthermore, the temperature and humidity control module can judge and output a corresponding operation instruction according to temperature and humidity values input by an external sensor, so that the switch cabinet can automatically maintain a proper working condition. In addition, the voice prompt part can effectively avoid misoperation of a user and avoid potential risks. The induction detection port and the automatic induction control module can automatically perform human body induction, so that a user can automatically operate when approaching or leaving the induction detection port, and the intelligence and the energy conservation of the device are improved. The high-voltage live display and locking area and the high-voltage live control module can improve the use safety of the device. Therefore, the intelligent measurement and control device for the switch cabinet improves the technical problem that the switch cabinet alarm in the prior art is single in function.

Drawings

FIG. 1 is a schematic structural diagram of an intelligent measurement and control device of a switch cabinet according to the present invention;

FIG. 2 is a schematic structural view of the intelligent measurement and control device of the switch cabinet in another direction;

FIG. 3 is a schematic diagram of the principle of the internal modules of the intelligent measurement and control device of the switch cabinet of the present invention;

fig. 4 is a temperature and humidity control logic diagram of an intelligent measurement and control device of a switch cabinet.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Referring to fig. 1 to fig. 3, an intelligent measurement and control device for a switch cabinet of the present invention includes: a main control panel 1 and a mounting backboard 2; the main control panel 1 and the installation back plate 2 are arranged oppositely. The main control panel 1 has a display portion 101, a touch portion 102, a plurality of knob portions 103, a dynamic simulation portion 104, a voice prompt portion 105, and a sensing probe port 106. The display part 101 is arranged above the side of the main control panel 1; the display unit 101 has a visible window 101a and an output operation state indication area 101 b; the output operation state indication area 101b is disposed below the visual window 101 a. The plurality of knob parts 103 are respectively arranged at two sides of the dynamic simulation part 104; the dynamic simulation part 104 is provided with a two-handcart test area 104a, a two-handcart working area 104b, a breaker on-position area 104c, a breaker dividing area 104d, a grounding switch on-position area 104e and a grounding switch dividing area 104 f; the two handcart test areas 104a and the two handcart working areas 104b are respectively arranged at two sides of the circuit breaker on-position area 104c and the circuit breaker dividing area 104 d; the grounding switch on area 104e and the grounding switch off area 104f are arranged below the handcart test area 104a and the handcart working area 104 b. The voice prompt unit 105 and the sensing probe port 106 are disposed on the other side of the dynamic simulation unit 104 with respect to the visible window 101a, and the voice prompt unit 105 is disposed below the sensing probe port 106. A main control module 3 is also arranged between the main control panel 1 and the installation backboard 2; the main control module 3 is provided with a temperature and humidity control module 301, a dynamic simulation control module 302, a wireless temperature measurement module 303, a voice prompt module 304, an in-cabinet control module 305 and an automatic induction control module 306. The temperature and humidity control module 301 is connected with the visible window 101 a; the dynamic simulation control module 302 is connected to the dynamic simulation unit 104; the wireless temperature measurement module 303 is connected with the temperature and humidity control module 301; the voice prompt module 304 is connected with the voice prompt part 105; the in-cabinet control module 305 is connected to the touch portion 102; the auto-sense control module 306 is connected to the sense probe port 106.

Specifically, the main control panel 1 and the installation backboard 2 are connected in a relatively openable and closable manner, and a temperature and humidity control module 301, a dynamic simulation control module 302, a wireless temperature measurement module 303, a voice prompt module 304, an in-cabinet control module 305 and an automatic induction control module 306 are arranged between the main control panel 1 and the installation backboard 2. The installation back plate 2 can be embedded and installed on the door plate or the periphery of the switch cabinet. The main control panel 1 is respectively provided with a display part 101, a touch part 102, a plurality of knob parts 103, a dynamic simulation part 104, a voice prompt part 105 and an induction detection port 106 so that each built-in working module is convenient for being recognized and controlled by a user.

Further, the mounting backboard 2 is provided with a first sensor connecting port 201, a second sensor connecting port 202 and a wireless sensor receiver 203; the first sensor connection port 201 and the second sensor connection port 202 are respectively connected with the temperature and humidity control module 301; the wireless sensing receiver 203 is connected with the wireless temperature measuring module 303. Specifically, the temperature and humidity control module 301 and the wireless temperature measurement module 303 are both connected to the visual window 101 a; therefore, when at least one of the first sensor connection port 201 and the second sensor connection port 202 is connected to an external temperature/humidity sensor, the specific values of the temperature/humidity of the switchgear field can be displayed on the visual window 101a in real time. And, the user can preset the upper and lower limit values of heating, air exhaust or dehumidification. The upper temperature limit and the lower temperature limit preset by the intelligent measurement and control device for the switch cabinet are respectively +15 ℃ and-5 ℃; the upper humidity limit is 90% RH and the lower humidity limit is 75% RH; the upper limit of air exhaust is +40 ℃, and the lower limit of air exhaust is-30 ℃. More specifically, referring to fig. 4, fig. 4 is a logic diagram of temperature and humidity control of an intelligent measurement and control device of a switch cabinet according to the present invention. As shown in fig. 4, when the ambient temperature measured by the external temperature/humidity sensor is less than or equal to the preset lower temperature limit or the measured humidity value is greater than or equal to the preset upper humidity limit, heating is started. And when the ambient temperature measured by the external temperature and humidity sensor is greater than or equal to a preset upper temperature limit value and the measured ambient humidity value is less than or equal to a preset lower humidity limit value, stopping heating. When the environmental temperature measured by an external temperature and humidity sensor is more than or equal to a preset upper air exhaust limit, starting air exhaust; and when the ambient temperature measured by the external temperature and humidity sensor is less than or equal to the preset lower air exhaust limit, the air exhaust is stopped. Therefore, the intelligent measurement and control device for the switch cabinet can realize automatic monitoring of the environment temperature and humidity of the switch cabinet and corresponding adjustment and improvement measures for the real-time temperature and humidity environment, so that the workload of maintenance and inspection personnel is reduced and the working efficiency of the maintenance and inspection personnel is improved. In addition, the wireless sensor receiver 203 provided in the intelligent measurement and control device for a switch cabinet of the present invention can directly transmit the temperature and humidity values with the external wireless temperature and humidity sensors, and transmit the received temperature and humidity values to the visible window 101a and the wireless temperature measurement module 303, respectively. The user can preset the temperature and humidity control value in the wireless temperature measurement module 303 through the touch portion 102, and when the numerical value measured by the external wireless temperature and humidity sensor exceeds the control range preset by the user, the alarm program preset by the intelligent measurement and control device for the switch cabinet can be triggered.

Further, the dynamic simulation control module 302 is in control connection with the dynamic simulation unit 104. More specifically, correctly insert this cubical switchboard intelligence measurement and control device with the auxiliary contact of outside handcart position after: when the contact of the working position of the handcart is closed, the handcart working area 104b lights a lamp of a red vertical simulation strip, and at the moment, the outside handcart is indicated to be positioned at the working position; when the handcart test position contact is closed, the handcart test area 104a lights the green horizontal simulation strip, and at the moment, the outside handcart is indicated to be located at the test position. Correctly insert this cubical switchboard intelligence measurement and control device with the auxiliary contact of the branch of outside circuit breaker, closing the position after: when the circuit breaker is in a closing state, the circuit breaker closing area 104c lights a lamp of the red vertical simulation strip, and at the moment, the circuit breaker is in the closing state; when the breaker is in the opening state, the breaker partition area 104d lights the green lamp of the inclined simulation bar, and at this time, the breaker is in the opening state. The auxiliary contact of the position of opening and closing of the external grounding switch is correctly inserted into the intelligent measurement and control device of the switch cabinet respectively: when the grounding knife is in a closing state, the grounding knife closing area 104e lights a lamp of the red vertical simulation strip, and at the moment, the grounding knife is in the closing state; when the grounding switch is in the open state, the grounding switch dividing area 104f lights the green lamp of the oblique simulation strip, and at this time, the grounding switch is in the open state. In addition, the dynamic simulation part 104 is also provided with an energy storage indicator lamp 104 g; the energy storage indicator light 104g is disposed adjacent to the circuit breaker engagement area 104 c. Specifically, after the auxiliary contact of the external energy storage mechanism is correctly connected into the intelligent measurement and control device of the switch cabinet, when the input contact is closed, the energy storage indicator lamp 104g is turned on. The user may preset that the energy storage indicator light 104g turns on the green light to indicate that the energy storage mechanism completes the energy storage action, and when the energy storage indicator light 104g turns on the red light to indicate that the energy storage mechanism is executing the energy storage action.

Further, the dynamic simulation part 104 is further provided with a high-voltage live display and locking area 104 h; the high-voltage live display and locking area 104h is arranged below the energy storage indicator lamp 104 g. In addition, the main control module 3 is also provided with a high-voltage electrification control module 307; the high-voltage electrification control module 307 is in control connection with the high-voltage electrification display and locking area 104 h. Specifically, the high-voltage electrification control module 307 arranged in the intelligent measurement and control device for the switch cabinet is suitable for a 3.6-40.5kV/50Hz system, is matched with a sensor with a corresponding voltage class for use, and can further control the high-voltage electrification display and locking area 104h to indicate the electrification condition of an external main loop. In particular, the short-circuit to ground output current of the sensor should be greater than 200 μ A. More specifically, when the voltages of the phases of the bus in the external main circuit are all less than 15% of the rated voltage, the high-voltage live control module 307 controls the forced locking device to be in the unlocked state, and meanwhile, the high-voltage live display and locking area 104h does not perform the lighting indication. When any phase voltage of the bus is greater than 50% of the preset rated voltage, the high-voltage electrification control module 307 controls the forced locking device to be in a locking state, and meanwhile, the high-voltage electrification display and locking area 104h is lighted for indication.

Further, the main control module 3 is connected to the voice prompt module 304; the voice prompt module 304 is in control connection with the voice prompt part 105. Specifically, when the external breaker and the grounding switch are in the closing position, if the trolley is pushed from the test position to the working position, the voice prompt unit 105 will send a prompt voice "please open the breaker and please tap the grounding switch". When the breaker is at a closing position, if the trolley is pushed to a working position from a test position, the voice prompt part 105 will send a prompt voice "please open the breaker". When the grounding knife is at the closing position, if the trolley is pushed to the working position from the test position, the voice prompt part 105 can send out a prompt voice of 'please tap the grounding knife'. Therefore, potential safety hazards caused by misoperation of a user can be effectively prevented.

Further, the main control module 3 is connected to the in-cabinet control module 305; the in-cabinet control module 305 is electrically connected to the touch portion 102 and the lighting system of the external switch cabinet, respectively. Specifically, under the interface that enables the window 101a to display the real-time temperature and humidity of the external switch cabinet, the user may select to turn on or off the lighting system of the external switch cabinet by touching the touch portion 102.

Further, the main control module 3 is in control connection with the auto-induction control module 306; the auto-sense control module 306 is electrically connected to the sensing probe port 106. In addition, the visual window 101a is provided with an LCD backlight function; the auto-sense control module 306 controls the LCD backlight function. Specifically, after a user leaves the intelligent measurement and control device of the switch cabinet for a preset time, the sensing detection port 106 sends a signal to the automatic sensing control module 306, so that the automatic sensing control module 306 controls the LCD backlight in the visual window 101a to be closed; thereby saving energy consumption. When a user approaches the intelligent measurement and control device of the switch cabinet for a preset time, the sensing detection port 106 sends a signal to the automatic sensing control module 306, so that the automatic sensing control module 306 controls the LCD in the visible window 101a to open backlight; thereby facilitating the operation of the user in dark environment. In addition, the automatic sensing control module 306 can also be connected to the in-cabinet control module 305, so that when a user approaches the sensing detection port 106, the lighting system of the external switch cabinet is automatically turned on; or when the user leaves the sensing detection port 106, the lighting system of the external switch cabinet is automatically turned off.

Further, the mounting backboard 2 is also provided with a plurality of access ends 204; the access end 204 is electrically connected with an information output end of an external switch cabinet; the access end 204 is electrically connected to the main control module 3. Thus, the visual window 101a can display the main loop current, voltage, active power, reactive power, power factor, and power parameters of the external switch cabinet. The user may switch the visual windows 101a to display different contents through the touch portion 102.

In summary, the intelligent measurement and control device of the switch cabinet is provided with a main control panel 1 and an installation back panel 2 respectively; the main control panel 1 is provided with a display part 101, a touch part 102, a plurality of knob parts 103, a dynamic simulation part 104, a voice prompt part 105 and an induction detection port 106; the main control panel 1 with be equipped with host system 3 between the installation backplate 2, and, host system 3 is respectively the control connection temperature and humidity control module 301, dynamic simulation control module 302, wireless temperature measurement module 303, voice prompt module 304, control module 305 in the cabinet, auto-induction control module 306 and high-voltage electrification control module 307. Therefore, the display part 101 can respectively indicate the main loop current, voltage, active power, reactive power, power factor, electric energy and other power parameters of the external switch cabinet; the touch portion 102 may control the display portion 101; the knob parts 103 can control an external switch cabinet; therefore, a user can remotely monitor the state of the switch cabinet in real time through the intelligent measurement and control device for the switch cabinet. In addition, the dynamic simulation part 104 can indicate the working state of the switch cabinet in real time through the car test area 104a, the car working area 104b, the circuit breaker on-position area 104c, the circuit breaker off-position area 104d, the grounding switch on-position area 104e, the grounding switch off-position area 104f, the energy storage indicator lamp 104g and the high-voltage live display and locking area 104h according to the circuit scheme of the connected switch cabinet, and further, when the switch cabinet is in an abnormal working state, the user can be assisted to quickly analyze and judge the reason of the abnormality. Further, the temperature and humidity control module 301 may determine and output a corresponding operation instruction according to a temperature and humidity value input by an external sensor, so that the switch cabinet may automatically maintain a suitable working condition. In addition, the voice prompt part 105 can effectively avoid misoperation of the user and avoid potential risks. The sensing detection port 106 and the auto-sensing control module 306 can automatically perform human body sensing, so that a user can automatically operate when approaching or departing from the sensing detection port 106, and the intelligence and energy conservation of the device are improved. The high voltage charging display and locking area 104h and the high voltage charging control module 307 can improve the use safety of the device. Therefore, the intelligent measurement and control device for the switch cabinet improves the technical problem that the switch cabinet alarm in the prior art is single in function.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (9)

1. The utility model provides a cubical switchboard intelligence measurement and control device which includes: a main control panel (1) and a mounting backboard (2); the main control panel (1) is arranged opposite to the mounting back plate (2); the main control panel (1) is provided with a display part (101), a touch part (102), a plurality of knob parts (103), a dynamic simulation part (104), a voice prompt part (105) and an induction detection port (106); the display part (101) is arranged above the side of the main control panel (1); the display unit (101) has a visible window (101a) and an output operation state indication area (101 b); the output working state indicating area (101b) is arranged below the visual window (101 a); the plurality of knob parts (103) are respectively arranged at two sides of the dynamic simulation part (104); the dynamic simulation part (104) is provided with a two-hand vehicle test area (104a), a two-hand vehicle working area (104b), a breaker on-position area (104c), a breaker partition area (104d), a grounding switch on-position area (104e) and a grounding switch partition area (104 f); the two handcart testing areas (104a) and the two handcart working areas (104b) are respectively arranged at two sides of the circuit breaker on-position area (104c) and the circuit breaker off-position area (104 d); the grounding switch on area (104e) and the grounding switch off area (104f) are arranged below the handcart test area (104a) and the handcart working area (104 b); the voice prompt part (105) and the induction detection port (106) are arranged on the other side of the dynamic simulation part (104) relative to the visual window (101a), and the voice prompt part (105) is arranged below the induction detection port (106); a main control module (3) is also arranged between the main control panel (1) and the mounting backboard (2); the main control module (3) is provided with a temperature and humidity control module (301), a dynamic simulation control module (302), a wireless temperature measurement module (303), a voice prompt module (304), an in-cabinet control module (305) and an automatic induction control module (306); the temperature and humidity control module (301) is connected with the visual window (101 a); the dynamic simulation control module (302) is connected with the dynamic simulation part (104); the wireless temperature measurement module (303) is connected with the temperature and humidity control module (301); the voice prompt module (304) is connected with the voice prompt part (105); the in-cabinet control module (305) is connected with the touch control part (102); the auto-induction control module (306) is connected with the induction probe port (106).

2. The intelligent measurement and control device of the switch cabinet according to claim 1, characterized in that: the mounting back plate (2) is provided with a first sensor connecting port (201), a second sensor connecting port (202) and a wireless sensor receiver (203).

3. The intelligent measurement and control device of the switch cabinet according to claim 2, characterized in that: the first sensor connection port (201) and the second sensor connection port (202) are respectively connected with the temperature and humidity control module (301).

4. The intelligent measurement and control device of the switch cabinet according to claim 3, characterized in that: the wireless sensing receiver (203) is connected with the wireless temperature measuring module (303).

5. The intelligent measurement and control device of the switch cabinet according to claim 1, characterized in that: the dynamic simulation part (104) is provided with an energy storage indicator lamp (104 g); the energy storage indicator lamp (104g) is arranged on the adjacent side of the circuit breaker on-position area (104 c).

6. The intelligent measurement and control device of the switch cabinet according to claim 5, characterized in that: the dynamic simulation part (104) is provided with a high-voltage live display and locking area (104 h); the high-voltage live display and locking area (104h) is arranged below the energy storage indicator lamp (104 g).

7. The intelligent measurement and control device of the switch cabinet according to claim 6, characterized in that: the main control module (3) is provided with a high-voltage electrification control module (307); the high-voltage electrification control module (307) is in control connection with the high-voltage electrification display and locking area (104 h).

8. The intelligent measurement and control device of the switch cabinet according to claim 1, characterized in that: the visual window (101a) is provided with an LCD backlight function; the auto-sense control module (306) controls the LCD backlight function.

9. The intelligent measurement and control device of the switch cabinet according to claim 8, characterized in that: the automatic induction control module (306) is connected with the in-cabinet control module (305).

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